A Stimuli-Responsive, Binary Reagent System for Rapid Isolation of

pp 10404–10410. DOI: 10.1021/acs.analchem.6b01961. Publication Date (Web): September 30, 2016. Copyright © 2016 American Chemical Society. *E-m...
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A Stimuli-Responsive, Binary Reagent System for Rapid Isolation of Protein Biomarkers Barrett James Nehilla, John J. Hill, Selvi Srinivasan, Yen-Chi Chen, Thomas H. Schulte, Patrick S. Stayton, and James J. Lai Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.6b01961 • Publication Date (Web): 30 Sep 2016 Downloaded from http://pubs.acs.org on October 7, 2016

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A Stimuli-Responsive, Binary Reagent System for Rapid Isolation of Protein Biomarkers Barrett J. Nehilla†, John J. Hill, Selvi Srinivasan, Yen-Chi Chen, Thomas H. Schulte, Patrick S. Stayton, James J. Lai* Department of Bioengineering, University of Washington, Seattle, WA 98195 Keywords: Stimuli-responsive, polymer-protein conjugates, immunoassays, SPR, ELISA

ABSTRACT

Magnetic microbeads exhibit rapid separation characteristics and are widely employed for biomolecule and cell isolations in research laboratories, clinical diagnostics assays and cell therapy manufacturing. However, micrometer particle diameters compromise biomarker recognition, which leads to long incubation times and significant reagent demands. Here, a stimuli-responsive binary reagent system is presented that combines the nanoscale benefits of efficient biomarker recognition and the microscale benefits of rapid magnetic separation. This system comprises magnetic nanoparticles and polymer-antibody (Ab) conjugates that transition from hydrophilic nanoscale reagents to microscale aggregates in response to temperature stimuli. The binary reagent system was benchmarked against Ab-labeled Dynabeads® in terms of biomarker isolation kinetics, assay speed and reagent needs. Surface plasmon resonance (SPR) measurements showed that polymer conjugation did not significantly alter the Ab’s binding affinity or kinetics. ELISA analysis showed that the unconjugated Ab, polymer-Ab conjugates and Ab-labeled Dynabeads exhibited similar equilibrium dissociation constants (Kd), ~ 2 nM.

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However, the binary reagent system isolated HIV p24 antigen from spiked serum specimens (150 pg/mL) much more quickly than Dynabeads, which resulted in shorter binding times by 10’s of minutes, or about 30-50% shorter overall assay times. The binary reagent system showed improved performance because the Ab molecules were not conjugated to large, solid microparticle surfaces. This stimuli-responsive binary reagent system illustrates the potential advantages of nanoscale reagents in molecule and cell isolations for both research and clinical applications.

INTRODUCTION Bioseparations capture molecules of interest for identification and quantification, or to clean up samples before downstream processing. Magnetic microbeads are employed as the solid supports in separations of cells[1],[2],[3], proteins[4],[5], oligonucleotides[6] and pathogens[7] because they provide accessible surfaces for immobilizing affinity reagents, and they respond sharply to a modest magnetic field for efficient separations[8]. These magnetic microbeads are standard reagents in clinical immunoanalyzer platforms such as the Beckman Coulter DxI and Access® systems and the Abbott Laboratories ARCHITECT system. Magnetic microbeads provide separation advantages due to their large diameters (≥ 1µm), but their use also imposes a paradox. The micrometer particle size imparts poor diffusion characteristics, which leads to long incubation times for antigen binding. Also, there are inefficiencies in Ab loading onto microparticle surfaces that lead to significant losses of Ab affinity. Thus, the properties of magnetic microbeads limit assay speeds, binding efficiencies and detection sensitivity. On the other hand, magnetic nanoparticles (< 50 nm) have many potential advantages related to their diffusive properties and binding capacity. However, most magnetic nanoparticles (mNPs) suffer

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from low magnetophoretic mobility, limiting their utility for separations using modest magnetic fields. We previously reported stimuli-responsive, polymer-coated mNPs that maintain the diffusive advantages of small nanoparticles while introducing switchable transitions to larger, aggregated mNPs with excellent magnetophoretic mobilities[9],[10]. Here, a binary reagent system is presented that comprises two stimuli-responsive reagents: mNPs and polymer-antibody (Ab) conjugates (Figure 1). Stimuli-responsive polymers, such as the temperature-responsive polymer poly(N-isopropylacrylamide), or pNIPAM, respond sharply and reversibly to physical or chemical stimuli by changing their conformation and physicochemical properties (e.g., from a hydrophilic state to a more hydrophobic state). This polymer displays lower critical solution temperature (LCST) behavior at solution temperatures of about 32°C[11], and this is saltcontrollable[12]. Stimuli-responsive polymers

like pNIPAM

have

been grafted

onto

surfaces[13],[14], membranes[15],[16] and gold nanoparticles[17] to capture, enrich and detect target biomolecules. They also have been used to synthesize micelles[18], hydrogels[19],[20], drug conjugates[21] and protein conjugates[22] for potential use as drug delivery devices. By decoupling the recognition component (polymer-Ab conjugate) from the separation component (mNPs), the diffusive and binding advantages of small nanoscale reagents are exploited. This system comes with the additional advantage of controllable transitions from a stable colloidal suspension to micron-sized aggregates with high magnetophoretic mobility.

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Figure 1. The stimuli-responsive binary reagent system, comprising stimuli-responsive magnetic nanoparticles (mNPs) and polymer-Ab conjugates. After application of an appropriate stimulus, the mNPs and conjugates co-aggregate with captured antigen to form magnetically-separable species. Reversing the stimulus provides the captured antigen free of magnetic particles. There is a need for more rapid and higher sensitivity p24 immunoassays. The HIV core protein p24 is a biomarker used to diagnose HIV infection[23]. Higher sensitivity p24 diagnostic tests would allow earlier detection of HIV to narrow the window period[24] and minimize the possibility of false negative readings. Faster p24 diagnostic tests would improve the throughput of clinical immunoanalyzers and have additional benefits for point-of-care assays in low resource settings[25]. Many laboratories have innovated technologies that could improve immunoassay performance, ranging from microfluidic platforms[5],[7], to two-phase systems[26]. However, conventional magnetic microbeads are used in most clinical immunoanalyzers. For example, magnetic microbeads (e.g., Dynabeads) are used to capture p24 in 4th generation HIV immunoassays such as the Abbott ARCHITECT HIV Ag/Ab Combo Test[4]. We hypothesized that the binding and capture of p24 would be faster with the nanoscale binary reagent system than with microscale magnetic beads. So, p24 was used as a model biomarker to benchmark the binding affinities and kinetics of the stimuli-responsive binary reagent system against Dynabeads.

EXPERIMENTAL SECTION

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Materials and Reagents. Information for materials and reagents is included in Supporting Information. PNIPAM Synthesis and Modification. Reversible addition-fragmentation chain transfer (RAFT) polymerization produced two classes of pNIPAM: one with a dodecyl (C12) tail and one with an ethyl (C2) tail. To produce pNIPAM with a C12 tail (C12-pNIPAM), NIPAM (9.38 g, 83 mmol), DMP (816 mg, 1.69 mmol), ACVA (47.4 mg, 0.160 mmol) and dioxane (23.5 g) were sealed in a round bottom flask, purged with N2 for 20 minutes and held at 70°C for 2 hours. To produce pNIPAM with a C2 tail (C2-PNIPAM), NIPAM (4.97 g, 43.9 mmol), ECT (32.6 mg, 0.0120 mmol), ACVA (3.5 mg, 0.001 mmol) and dioxane (12.5 g) were sealed in a round bottom flask, purged with N2 for 20 minutes and held at 70°C for 4 hours. The polymers were collected by precipitation into 90% pentane/10% ether followed by vacuum drying. To produce an aminereactive NHS ester (pNIPAM-NHS), C2-pNIPAM (2.5 g) and NHS (0.016 g) were dissolved in 10 mL DCM. DCC (0.029 g) was added to this solution, and the reaction was mixed at 20°C for 24 hours. The polymer was collected by precipitation into pentane and dried in vacuo. The polymer characterizations using SEC and NMR are included in the Supporting Information. Polymer-Antibody Conjugate Preparation. Polymer-Ab conjugates were prepared at a polymer:antibody molar ratio of 100:1. Anti-HIV-1 p24 monoclonal antibody was obtained through the NIH AIDS Reagent Program, Division of AIDS, NIAID, NIH:HIV-1 p24 Hybridoma (183-H12-5C) from Dr. Bruce Chesebro[27]. The Ab was diluted into 25 mM Na2CO3/NaHCO3, pH 9.5 and cooled. The pNIPAM-NHS was injected into the Ab solution and mixed for 18 hours at 4°C. Free polymer was removed by ultrafiltration with 100 kDa MWCO centrifugal filter units (Millipore) or by aqueous SEC (Supporting Information). Characterization and functional assays of the polymer-Ab conjugates are given in the Supporting Information.

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Magnetic Nanoparticle (mNP) Synthesis and Purification. Magnetic nanoparticles coated with pNIPAM were synthesized with modifications of previous protocols[9]. C12-pNIPAM (0.9 g, 0.138 mmol) was solubilized in 50 mL tetraglyme at 100°C for 30 minutes. Next, Fe(CO)5 (200 µL, 1.48 mmol) was injected into the polymer solution and the temperature was increased to 190°C. The reaction was held at 190°C for 6 hours. The polymer-coated mNPs were collected by precipitation into pentane and then dried in vacuo. Then, the mNPs were subjected to ultrafiltration in DH2O with a 100 kDa MWCO membrane and lyophilized. Surface Plasmon Resonance (SPR) Biosensor Experiments. The binding affinities of the Ab and polymer-Ab conjugates were measured by SPR. Running conditions and instrument details are given in the Supporting Information. Seven p24 (analyte) samples, from 50.0 nM to 68.6 pM, were prepared in HBS-EP, and each was run in a mixed order, in triplicate. This approach assessed the reproducibility of binding and managed potential systematic bias to the order of injection. Multiple blank (buffer) injections were used to assess and subtract system artifacts. The association and dissociation phases for all analyte concentrations were monitored for 240 seconds (s) and 600 s, respectively, at a flow rate of 75 µL/min. Longer dissociation phase experiment of 5400 s also was performed with the 16.7 nM p24 sample at a flow rate of 75 µL/min. Between experiments, the surfaces were regenerated with 10 mM glycine, pH 1.5 for 30 s, at a flow rate of 50 µL/min. SPR analyses are given in the Supporting Information. ELISA-Based Binding of anti-p24, polymer-Ab conjugates and Dynabeads-anti-p24. A competitive ELISA (developed in-house) measured the apparent binding affinities of unconjugated Ab, polymer-Ab conjugates and Dynabeads-anti-p24 for p24 antigen. The monoclonal anti-p24 IgG used in this ELISA was from the NIH AIDS Reagent Program[27], and the ELISA protocol has been published elsewhere[28]. ELISA analyses via BIOEQS to determine

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the Kd values for unconjugated Ab, polymer-Ab conjugates and Dynabeads-anti-p24 are given in the Supporting Information. HIV-1 p24 – Antibody Reaction Kinetics. The p24 binding kinetics of the binary reagent system and the Dynabeads-anti-p24 were compared. Samples in 10 mM PBS with final concentrations of 150 pg/mL p24, 2 mg/mL mNPs, 5% human serum, 350 mM NaCl and 1.938 µg/mL polymerAb conjugate were mixed for 0, 1, 2.5, 5, 10 or 15 minutes at 20°C. After incubating, the mNPs and conjugates were co-aggregated by warming at 37°C for 2 minutes and isolated with a magnetic field for 2 minutes at 37°C. The supernate was analyzed for free p24 via ELISA[28]. For the Dynabeads-anti-p24, samples in 10 mM PBS (350 mM NaCl) with final concentrations of 150 pg/mL p24, 5% human serum and 242 µg/mL Dynabeads-anti-p24 (1.938 µg/mL Ab equivalent) were prepared. The incubation, heating and magnetic separation steps were identical to that of the binary reagent system experiments. The anti-p24 IgG:p24 antibody:antigen molar ratio for both the binary reagent system and the Dynabeads-anti-p24 was 2000:1, creating a 4000:1 ratio of antibody binding sites:p24. This ratio was chosen from ELISA-based binding experiments above. Simulations of the reaction kinetics, as binding progress curves, were also performed, as described in the Supporting Information.

RESULTS AND DISCUSSION The binary reagent assay system. The binary reagent system comprises stimuli-responsive mNPs and polymer-Ab conjugates. The C12-pNIPAM was synthesized via RAFT polymerization[29]. The physical and chemical properties of C12-pNIPAM were shown in Supporting Figure 1. The C12-pNIPAM was then used to synthesize stimuli-responsive mNPs, which comprised iron oxide cores coated with pNIPAM[9-10]. All experiments were performed

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with two different batches of mNPs (20.0 ± 0.45 nm diameter, measured by dynamic light scattering). The thermoresponsive character of the mNPs was shown by the LCST (n=2) of 36.4 ± 0.085°C in PBS (Figure 2A). The mNP LCST was ~6°C greater than literature values for pNIPAM[11]. The mNPs zeta potentials were ~0 to -10 mV (data not shown), so we hypothesize that the higher LCST values for the mNPs was due to electrostatic repulsion of the negatively charged particle surfaces. The pNIPAM polymer was also salt-responsive[12]. The addition of 200 mM NaCl to mNPs in PBS decreased the LCST (n=2) from 36.4 ± 0.085°C to 32.3 ± 0.233°C (Figure 2A). Therefore, all experiments were performed in solutions with 350 mM final NaCl concentration (150 mM NaCl in PBS, 200 mM NaCl additional), in which a temperature stimulus of 37°C aggregated mNPs for separation. In fact, after warming mNPs to 37°C for 2 minutes, 95% of the mNPs were magnetically separated within 30 seconds (Figure 2B). However, the mNPs are stable colloids, so they can only be separated after they are aggregated by a heat/salt stimulus. For example, in non-aggregated state (Figure 2D, 0 seconds),